JP2008519290A - Audio signal encoding and decoding using complex-valued filter banks - Google Patents

Abstract

  The encoder (109) comprises a receiver (201) for receiving a time domain audio signal. The filter bank (203) generates a first subband signal from the time domain audio signal. The first subband signal corresponds to a complex subband domain representation of the non-critically sampled time domain signal. The transform processor (205) generates a second subband signal from the first subband signal by subband processing. The second subband signal corresponds to a subband domain representation of a critically sampled time domain audio signal. The encoding processor (207) then generates a waveform encoded data stream by encoding the data values of the second subband signal. The transform processor (205) generates the second subband signal by direct subband transform without transforming back to the time domain. According to the present invention, it is possible to perform waveform coding on an oversampled subband signal generated by parametric coding with a reduced amount of calculation. The decoder performs the inverse operation.

Description

  The present invention relates to encoding and / or decoding of an audio signal, and more particularly to waveform encoding / decoding of an audio signal.

  Digital encoding of various source signals has become more important over the last few decades as analog representations and communications have been replaced by digital signal representations and communications. For example, mobile telephone systems such as GSM are based on digital speech coding. In addition, distribution of media content such as video and music is further based on digital content coding.

  Conventionally, audio coding mainly uses waveform coding in which the underlying waveform is digitized and coded efficiently. For example, a typical waveform encoder includes a filter bank that converts a signal to the frequency subband domain. A masking threshold is applied based on the psychoacoustic model, and the resulting subband values are efficiently quantized and encoded using, for example, a Huffman code.

  Examples of waveform encoders include the well-known MPEG-1 layer 3 (often represented as MP3) or AAC (Advanced Audio Coding) encoding techniques.

  In recent years, the underlying waveform has not been directly encoded, but rather several encoding techniques have been proposed that characterize the encoded signal by several parameters. For example, in the case of speech coding, the encoder and decoder may be based on a model of the human vocal tract, and instead of encoding the waveform, it encodes the various parameters and excitation signals of the model. Can do. The above-described method is generally expressed as a parametric coding method.

  Furthermore, particularly efficient and high-quality encoding can be realized by combining waveform encoding and parametric encoding. In the system described above, the parameter can represent a portion of the signal with reference to another portion of the waveform encoded signal. For example, an encoding method has been proposed in which a low frequency is waveform-encoded and a high frequency is encoded by parametric extension that expresses the characteristics of the high frequency relative to the low frequency. As another example, for example, multi-channel signal coding has been proposed in which a mono signal is waveform coded and the parametric extension has parameter data indicating how the individual channels differ from the common signal.

  Examples of parametric extended coding techniques include spectral band replication (SBR) techniques, parametric stereo (PS) techniques, and spatial audio coding (SAC) techniques.

  Currently, SAC techniques are being developed to efficiently encode multi-channel audio signals. This technique is based in part on the PS coding technique. Similar to the PS paradigm, SAC efficiently represents a multi-channel signal with M channels, with a signal with N channels (N <M) and a small amount of parameters representing spatial cues. Is based on the concept that is possible. Typical applications include encoding a normal 5.1 signal representation as a waveform encoded mono or stereo signal plus a spatial parameter. It is possible to embed the spatial parameters in the auxiliary data part of the mono or stereo core bit stream to form a backward compatible extension.

  Similar to the SBR and PS methods, SAC uses a complex (pseudo) orthogonal mirror filter to convert the time domain representation to the frequency domain representation (and vice versa). A characteristic of the filter bank described above is that complex-valued subband domain signals can be effectively oversampled by a factor of two. This allows post-processing operations of subband domain signals that do not introduce aliasing distortion.

  Another of the normal characteristics of parametric extensions is that under normal conditions, the above approach does not achieve a transparent audio quality level (ie, results in some quality degradation). .

  Encode a specific portion of a complex subband domain signal (eg, a specific number of bands) using a waveform encoder to extend parametric extensions such as SBR, PS and SAC toward transparent audio quality It is desirable to do.

  The simple technique first includes a step of converting the above-described complex subband domain portion back to the time domain. An existing waveform encoder (eg, AAC) can then be applied to the resulting time domain signal. However, the above approach has several drawbacks.

  In particular, the resulting encoder and decoder complexity is large and has a large computational load because of the repeated transformations between the frequency domain and the time domain using various transformations. For example, if the parametric extension utilizes time domain signal encoding obtained after QMF synthesis, the corresponding decoder has a full waveform decoder (eg, an AAC derivative decoder), in addition to Has an analysis QMF bank. This is costly in terms of computational complexity.

  Furthermore, it would be advantageous to have a correlation between the parametric extension used and the waveform encoding of the signal elements encoded by the parametric extension.

  By way of example, the system can have, for example, AAC and SBR (HE-AAC) coding, or AAC and SAC coding. If the system allows the SBR or SAC extensions to be enhanced by waveform encoding, it is natural to use AAC to encode the time domain signal obtained after QMF synthesis. However, another system using the same extension (eg, a combination of MPEG-I layer II and SBR) preferably uses another waveform coding system (ie, MPEG-I layer II). Thus, it becomes effective to couple the waveform encoding enhancement to the parameter expansion tool rather than to the core encoder.

  Thus, the improved system is effective. In particular, increased flexibility, reduced computational complexity, reduced computational load, facilitated interoperability between the various elements of the encoding performed, improved audio quality (eg scalable audio quality), and / or An encoding / decoding system that can improve performance becomes effective.

  Thus, the present invention preferably seeks to mitigate, alleviate or eliminate one or more of the above disadvantages alone or in any combination.

  According to an aspect of the present invention, a decoder is provided that generates a time domain audio signal by waveform decoding. The decoder is means for receiving an encoded data stream and means for generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is Means for corresponding to a complex subband domain signal representation of a critically sampled time domain audio signal, and conversion means for generating a second subband signal from the first subband signal by subband processing, The subband signal comprises transform means corresponding to a complex subband domain representation of the non-critically sampled time domain audio signal and a synthesis filter bank for generating the time domain audio signal from the second subband signal.

  The present invention may allow for decoder improvements. A decoder with reduced computational complexity can be achieved and / or computational resource requirements can be reduced. In particular, the synthesis filter bank can be used for both parametric extension decoding and waveform decoding of time domain audio signals. It is possible to achieve commonality between waveform decoding and parametric decoding. In particular, the synthesis filter bank can usually be used for parametric decoding in parametric extension coding techniques such as SBR, PS, and SAC.

  The transform processor is configured to generate the second subband signal by subband processing without requiring any transformation (eg, returning the first subband signal to the time domain).

  The decoder may further comprise means for performing non-aliased signal processing on the second subband signal prior to the synthesis operation of the synthesis filter bank.

  According to an optional feature of the invention, each subband of the first subband signal comprises a plurality of partial subbands, and the transforming means converts the subband of the second subband signal to the first subband. A second synthesis filter bank is provided that generates from partial subbands of the band signal.

  This can provide an efficient means of converting the first subband signal. The above features may provide provisions for efficient and / or computationally efficient means of compensating the frequency response of the subband filters of the synthesis filter bank.

  According to an optional feature of the invention, each subband of the second subband signal comprises an alias band and a non-alias band, and the transforming means is a partial subband of the first subband signal. Are separated into an aliased subband of the first subband band of the second subband signal and a non-aliased subband of the second subband of the second subband signal. Alias subbands have corresponding frequency intervals in the time domain signal.

  This can provide an efficient means of converting the first subband signal. In particular, signal components in different subbands originating from the same frequency in the time domain audio signal may be allowed to be generated from a single signal component.

  According to an optional feature of the invention, the separating means has a butterfly structure. The butterfly structure can generate two output values corresponding to different subbands of the second subband using one zero value input and one partial subband data value input.

  According to another aspect of the invention, an encoder is provided for encoding a time domain audio signal. The encoder is a means for receiving a time domain audio signal and a first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal is a time domain signal. A first filter bank corresponding to a non-critically sampled complex subband domain representation; and transform means for generating a second subband signal from the first subband signal by subband processing, comprising: A subband signal generates a waveform encoded data stream by encoding transform means corresponding to a complex subband domain representation of a critically sampled time domain audio signal and a data value of the second subband signal. Means.

  The present invention may allow for improved encoders. An encoder with reduced computational complexity can be achieved and / or computational resource requirements can be reduced. It is possible to achieve commonality between waveform coding and parametric coding. In particular, the first filter bank may be a QMF filter bank that is typically used for parametric encoding in parametric extended encoding techniques such as SBR, PS, and SAC.

  An improvement in the decoded audio quality can be achieved. For example, the time domain audio signal may be a residual signal from parametric coding. The waveform encoded signal can provide information that provides improved transparency.

  The transform processor is configured to generate the second subband signal by subband processing without requiring any transformation (eg, returning the first subband signal to the time domain).

  According to an optional feature of the invention, the encoder further comprises means for parametrically encoding the time domain audio signal using the first subband signal.

  The present invention may use both parametric coding and waveform coding to enable efficient and / or high quality coding of the underlying signal. Functions can be shared between parametric coding and waveform coding. The parametric coding may be parametric extension coding such as SBR, PS or SAC coding. In particular, the encoder may provide provision for waveform coding of some or all subbands of parametric extension coding.

  According to an optional feature of the invention, the converting means comprises a second filter bank that generates a plurality of subbands for each subband of the first subband signal.

  This can provide an efficient means of converting the first subband signal. The above features may provide for an efficient and / or computationally efficient means of compensating the frequency response of the first subband subband filter.

  According to an optional feature of the invention, the second filter bank is stacked with an odd number.

This can improve performance and allow for improved separation between positive and negative frequencies in the complex subband region.

According to an optional feature of the invention, each subband includes a specific alias subband corresponding to the subband alias band and a specific nonalias partial subband corresponding to the subband non-alias band. And converting means comprises combining means for combining the alias sub-band of the first sub-band with the non-alias sub-sub-band of the second sub-band. Alias partial subbands have corresponding frequency intervals in the time domain signal.

  This can provide an efficient means of converting the first subband signal. In particular, signal components in different subbands originating from the same frequency in the time domain audio signal may be allowed to be combined into a single signal component. This may allow a data rate reduction.

  According to an optional feature of the invention, the synthesis means is configured to reduce energy in the alias band.

  This can improve performance and / or allow a reduction in data rate. In particular, the energy in the alias band can be minimized and the alias band can be ignored.

  In particular, the combining means may further comprise means for compensating the non-aliased partial subband of the first subband band by the aliased subband of the second subband. In particular, the combining means may comprise means for subtracting the alias subband coefficients of the second subband from the non-aliased partial subbands of the first subband.

  According to an optional feature of the invention, the combining means comprises a non-aliased sum signal of the first alias partial subband in the first subband and the first non-aliased partial subband in the second subband. Means for generating.

  This may allow efficient implementation and / or high performance.

  According to an optional feature of the invention, the synthesis means comprises a butterfly structure for generating a non-aliased sum signal.

  This may allow a particularly efficient implementation and / or high performance. The butterfly structure may in particular be a half butterfly structure in which only one output value is generated.

  According to an optional feature of the invention, the at least one coefficient of the butterfly structure depends on the frequency response of the filter of the first filter bank.

  This may allow a particularly efficient implementation and / or high performance.

  According to an optional embodiment of the invention, the transforming means is configured not to comprise alias band data values in the encoded data stream.

  This may allow high encoded audio quality for specific data rates.

  According to an optional feature of the invention, the encoder further comprises means for performing non-aliased signal processing on the first subband signal prior to conversion to the second signal.

  This can improve performance. The present invention allows for efficient implementation of a waveform encoder with critical sampled output signals while allowing individual subband signal processing without introducing aliasing errors .

  According to an optional feature of the invention, the encoder further comprises means for phase compensating the first subband signal prior to conversion to the second signal.

  This can improve performance and / or provide for an efficient implementation.

  According to an optional feature of the invention, the first filter bank is a QMF filter bank.

  The present invention may enable efficient waveform coding using a QMF filter used in many parametric coding techniques such as SBR, PS, SAC. Accordingly, it is possible to improve the compatibility between the waveform coding method and the parametric coding method and / or improve the function and / or improve the interoperability.

  According to another aspect of the present invention, a method for generating a time domain audio signal by waveform decoding is provided. The method includes receiving an encoded data stream and generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is: Corresponding to a complex subband domain signal representation of a critically sampled time domain audio signal, and generating a second subband signal from the first subband signal by subband processing, comprising: The band signal corresponding to a complex subband domain representation of the non-critically sampled time domain audio signal, and the synthesis filter bank generating the time domain audio signal from the second subband signal.

  According to another aspect of the present invention, a method for encoding a time domain audio signal is provided. The method includes receiving a time domain audio signal and a first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is the time domain signal. Corresponding to a non-critically sampled complex subband region representation and generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is: A step of responding to a critical subsampled complex subband domain representation of the time domain audio signal and a step of generating a waveform encoded data stream by encoding the data values of the second subband signal are provided.

  According to another aspect of the invention, a receiver for receiving an audio signal is provided. The receiver is means for receiving an encoded data stream and means for generating a first subband signal by decoding a data value of the encoded data stream, wherein the first subband signal is Means for corresponding to a complex subband domain signal representation of a critically sampled time domain audio signal, and conversion means for generating a second subband signal from the first subband signal by subband processing, The subband signal comprises transform means corresponding to a complex subband domain representation obtained by non-critically sampling the time domain audio signal, and a synthesis filter bank for generating the time domain audio signal from the second subband signal.

  According to another aspect of the invention, a transmitter for transmitting an encoded audio signal is provided. The transmitter is a means for receiving a time domain audio signal and a first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal receives the time domain signal. A first filter bank corresponding to a non-critically sampled complex subband domain representation; and transform means for generating a second subband signal from the first subband signal by subband processing, comprising: A subband signal generates a waveform encoded data stream by encoding transform means corresponding to a complex subband domain representation of a critically sampled time domain audio signal and a data value of the second subband signal. Means and means for transmitting the waveform encoded data stream.

  According to another aspect of the present invention, a transmission system for transmitting a time domain audio signal is provided. The transmission system includes a transmitter and a receiver. The transmitter is a means for receiving a time domain audio signal and a first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal receives the time domain signal. A first filter bank corresponding to a non-critically sampled complex subband domain representation; and transform means for generating a second subband signal from the first subband signal by subband processing, comprising: A subband signal generates a waveform encoded data stream by encoding transform means corresponding to a complex subband domain representation of a critically sampled time domain audio signal and a data value of the second subband signal. Means and means for transmitting the waveform encoded data stream. The receiver comprises means for receiving a waveform encoded data stream and means for generating a third subband signal by decoding a data value of the encoded data stream, wherein the third subband signal Means for corresponding to a complex subband domain signal representation of a critically sampled time domain audio signal, and conversion means for generating a fourth subband signal from the third subband signal by subband processing, 4 subband signals comprise transform means corresponding to a complex subband domain representation of non-critically sampled time domain audio signals, and a synthesis filter bank for generating the time domain audio signals from the fourth subband signals. .

  According to another aspect of the present invention, a method for receiving an audio signal is provided. The method includes receiving an encoded data stream and generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is: Corresponding to a complex subband domain signal representation of a critically sampled time domain audio signal, and generating a second subband signal from the first subband signal by subband processing, comprising: The band signal corresponding to a complex subband domain representation of the non-critically sampled time domain audio signal, and the synthesis filter bank generating a time domain audio signal from the second subband signal.

  According to another aspect of the invention, a method for transmitting an encoded audio signal is provided. The method includes receiving a time domain audio signal and a first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is the time domain signal. Corresponding to a non-critically sampled complex subband region representation and generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is: Corresponding to a complex subband domain representation of a critically sampled time domain audio signal, generating a waveform encoded data stream by encoding data values of the second subband signal, and waveform encoding Transmitting a data stream.

  According to another aspect of the invention, a method for transmitting and receiving a time-domain audio signal is provided. The method includes: a transmitter receiving a time domain audio signal; and a first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is Corresponding to a non-critically sampled complex subband domain representation of the time domain signal and generating a second subband signal from the first subband signal by subband processing, the second subband signal comprising: A band signal corresponding to a complex subband domain representation of a critically sampled time domain audio signal; and generating a waveform encoded data stream by encoding data values of a second subband signal; Transmitting the waveform-encoded data stream; and a step in which the receiver receives the waveform-encoded data stream. Generating a third subband signal by decoding a data value of the encoded data stream, wherein the third subband signal is a complex subband obtained by critically sampling a time domain audio signal A step corresponding to the domain signal representation, and a step of generating a fourth subband signal from the third subband signal by subband processing, wherein the fourth subband signal converts the time domain audio signal into a non-critical Corresponding to the sampled complex subband domain representation, and the synthesis filter bank generating a time domain audio signal from the fourth subband signal.

  According to another aspect of the present invention, a computer program for performing any of the methods described above is provided.

  The foregoing and other aspects, features and advantages of the invention will be apparent from and will be elucidated with reference to the embodiments described hereinafter.

  Embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings.

  FIG. 1 illustrates a transmission system 100 for communication of audio signals according to a particular embodiment of the present invention. The transmission system 100 comprises a transmitter 101 coupled to a receiver 103 via a network 105 which can be in particular the Internet.

  In this particular example, the transmitter 101 is a signal recording device and the receiver is a signal player device 103, but in other embodiments, the transmitter and receiver are used for other applications and for other purposes. Can do. For example, the transmitter 101 and / or the receiver 103 may be part of a transcalling function, and may include, for example, an interface with another signal source or destination.

  In a specific example where the signal recording function is supported, the transmitter 101 comprises a digitizer 107 that receives an analog signal (converted to a digital PCM signal by sampling and analog-to-digital conversion).

  Transmitter 101 is coupled to encoder 109 of FIG. The encoder 109 encodes the PCM signal using an encoding algorithm. Encoder 100 is coupled to network transmitter 111. The network transmitter 111 receives the encoded signal and interfaces with the Internet 105. The network transmitter may transmit the encoded signal to the receiver 103 via the Internet 105.

  The receiver 103 includes a network receiver 113. The network receiver 113 interfaces with the Internet 105 and is configured to receive an encoded signal from the transmitter 101.

  Network receiver 111 is coupled to decoder 115. Decoder 115 receives the encoded signal and decodes it with a decoding algorithm.

  In the specific example where the signal playback function is supported, the receiver 103 further comprises a signal player 117 that receives the decoded audio signal from the decoder 115 and presents it to the user. In particular, the signal player 113 may include a digital / analog converter, an amplifier, and a speaker necessary for outputting a decoded audio signal.

  FIG. 2 shows the encoder 109 of FIG. 1 in more detail. The encoder 109 includes a receiver 201 that receives a time domain audio signal to be encoded. The audio signal can be received from any external or internal source (such as from a local signal storage device).

  The receiver is coupled to the first filter bank 203. The first filter bank 203 generates a subband signal comprising a plurality of separate subbands. In particular, the first filter bank 203 may be a QMF filter bank known by parametric coding techniques such as SBR, PS and SAC. Thus, the first filter bank 203 generates a first subband signal corresponding to a complex subband domain representation that non-critically samples the time domain signal. In this particular example, the first subband signal has an oversampling factor of 2, which is well known for complex modulation QMF filters.

  Since each QMF band is oversampled twice, many signal processing operations can be performed on individual subbands without introducing any aliasing distortion. For example, each individual subband can be scaled and / or can be added or subtracted from other subbands, for example. Thus, in particular embodiments, encoder 109 further comprises means for performing non-aliased signal processing operations on the QMF subband.

  The first subband signal corresponds to a subband signal normally generated by a parametric extension coder such as SBR, PS, or SAC. Therefore, the parametric extension coding of the time domain signal can be generated using the first subband signal. Further, the same subband signal in encoder 109 of FIG. 2 is also used for waveform coding of the time domain signal. Thus, the encoder 109 can use the same filter bank 203 for parametric coding and waveform coding of the signal.

  The main challenge in the waveform coding of the complex-valued subband domain representation of the first subband signal is that it does not represent a compact representation (ie oversampled twice). Encoder 109 uses modified discrete cosine transform (MDCT) (for example, see “Signal Processing with Lapped Transform, Artech House, Boston, London, 1992” by MD Malvar for an explanation of MDCT) based on original time. The complex subband domain representation is directly converted to an expression that approximates the expression obtained when applied directly to the domain signal. This expression, similar to MDCT, is critically sampled. As such, this signal is suitable for known perceptual audio coding techniques that can be applied to efficiently encode the resulting representation and provide efficient waveform coding.

  In particular, the encoder 109 comprises a transform processor 205 that generates a second subband signal from the first subband signal by performing a complex transform on the individual subbands of the first subband signal. The second subband signal corresponds to a complex subband domain representation of a critically sampled time domain audio signal.

  Thus, in encoder 109, transform processor 205 outputs a QMF filter bank output that is compatible with a normal current parametric extension encoder, with a critical signal that closely corresponds to the subband signal normally generated in a normal waveform encoder. Convert to sampled MDCT-like subbands.

  Therefore, instead of using QMF conversion and MDCT conversion, the first subband signal is directly processed in the subband region to generate the second subband signal. The second subband signal can be handled as an MDCT signal of a normal waveform encoder. Thus, it is possible to apply known techniques for encoding subband signals, for example, it is possible to achieve efficient waveform coding of the residual signal from parametric extended coding (time Without requiring conversion to a region). Therefore, it is possible to eliminate the requirement for the QMF synthesis filter.

  In this example, encoder 109 comprises an encoding processor 207 coupled to transform processor 205. The encoding processor 207 receives a critically sampled second subband signal similar to MDCT from the transform processor 205 and, for example, normal waveform codes such as quantization, scale factor, Huffman coding, etc. This is encoded using the encoding method. The resulting encoded data is embedded in the encoded data stream. The data stream may further comprise other encoded data such as, for example, parametric encoded data.

  As will be described in more detail below, transform processor 205 uses the basic filter (or prototype filter) information of first filter bank 203 to in a non-alias band (or pass band). Combining signal components from separate subbands and removing signal components from alias bands (or stopbands). Therefore, it is possible to ignore the alias band frequency component for each subband. This results in a critical sampled signal without oversampling.

  In particular, as described below, the transform processor 205 includes a second filter that generates a plurality of subbands for each subband of the QMF filter bank. Thus, the subband is divided into further partial subbands. Due to the overlap between the QMF filters, a particular signal component of the time domain signal (eg, a sine wave at a particular frequency) can result in a signal component in two separate QMF subbands. The second filter bank further divides the aforementioned subband so that the signal component is represented in a partial subband of the first QMF subband and represented in a partial subband of the second QMF subband. . The data values of the above two partial subband signals are supplied to the synthesizer. The combiner combines the two signals to produce a single signal component. This signal component is then encoded by the encoding processor 207.

  FIG. 3 shows examples of specific elements of the transformation processor 205. In particular, FIG. 3 shows a first transform filter bank 301 for a first QMF subband and a second transform filter for a second QMF subband. Signals from partial subbands corresponding to the same frequency are then provided to synthesizer 305. The combiner 305 generates a single output data value for the partial subband.

  Decoder 115 can perform the inverse operation of encoder 109. FIG. 4 shows the decoder 115 in more detail.

  The decoder includes a receiver 401 that receives the signal encoded by the encoder 109 from the network receiver 113. The encoded signal is transferred to the decoding processor 403. The decoding processor 403 decodes the waveform encoding of the encoding processor 207. Thereby, the critically sampled subband signal is reproduced. This signal is supplied to the decoding conversion processor 405. The conversion processor 405 reproduces the non-critically sampled subband signal by performing the inverse operation of the conversion processor 205. The non-critically sampled signal is then provided to the QMF synthesis filter 407. The QMF synthesis filter 407 generates a decoded version of the original time domain audio encoded signal.

  In particular, the decoding transform processor 405 includes a splitter (such as an inverse butterfly structure) that reproduces signal components in partial subbands that have signal bands in both alias and non-alias bands. The partial subband signal is then fed to a synthesis filter bank corresponding to the transform filter bank 301, 303 of the encoder 109. The output of the foregoing filter bank corresponds to a non-critically sampled subband signal.

  Specific embodiments of the invention are described in further detail below. The description of the embodiment will be described with reference to the encoder structure 500 of FIG. The encoder structure 500 can be implemented in particular in the encoder 109 of FIG.

  The encoder structure 500 comprises a 64 band analysis QMF filter bank 501.

  The QMF analysis subband filter can be described as follows. Given a real-valued linear phase prototype filter p (y), the complex modulation analysis filter bank of M bands is the analysis filter

（サブバンド係数k=0,1,…,M−1）によって定義することが可能である。位相パラメータθは、以下の解析に対する重要性を有する。通常選ぶのは（N+M）/2である。ここで、Nはプロトタイプ・フィルタの次数である。

(Subband coefficients k = 0, 1,..., M−1). The phase parameter θ has importance for the following analysis. The normal choice is (N + M) / 2. Where N is the order of the prototype filter.

_{Given a} real-valued discrete-time signal x (v), the subband signal v _k (n) filters (convolves) x (v) with h _k (v) and then FIG. 6 (encoder 109). And the left side of the decoder 115 QMF analysis filter bank and QMF synthesis filter bank operations) is obtained by downsampling the result by a factor of M.

As shown on the right side of FIG. 6, the synthesis operation first includes the step of up-sampling the QMF subband signal by a factor of M, followed by the step of filtering with a complex modulation filter of the same type as Equation (1), A step of adding and a step of doubling the real part at the end are provided. In the above case, the almost complete reconstruction of the real-valued input signal x (v) is described by P. Ekstrand, `` Bandwidth extension of audio signals by spectral band replication, Proc. 1 ^st IEEE Benelux Workshop on Model based Processing and Coding of Audio. (MPCA-2000), pp. 53-58, Leuven, Belgium, November 15 2002 ”, can be obtained by appropriate design of a real-valued linear phase prototype filter p (v).

  Below,

を離散時間信号z(n)の離散時間フーリエ変換とする。

Is the discrete-time Fourier transform of the discrete-time signal z (n).

  In addition to the almost perfect reconstruction characteristics of the QMF bank, P (ω) (Fourier transform of p (v)) shall be virtually zero outside the frequency interval [−π / M, π / M]. .

  The Fourier transform of the downsampled complex subband domain signal is

によって表される。ここで、kはサブバンド係数であり、Mはサブバンドの数である。プロトタイプ・フィルタの周波数応答が制限されるという前提によって、式（２）における和は、ω毎に一項しか有していない。

Represented by Here, k is a subband coefficient, and M is the number of subbands. Due to the assumption that the frequency response of the prototype filter is limited, the sum in equation (2) has only one term per ω.

  The corresponding stylized absolute frequency response is shown in FIGS.

  In particular, FIG. 7 shows the stylized frequency response of the first few frequency bands of the complex QMF bank 501 before downsampling. FIG. 8 shows the standardized frequency response of a downsampled complex QMF bank for even (upper) subband k and odd (lower) subband k. Therefore, as shown in FIG. 8, the center of the QMF filter band is aliased to π / 2 in the case of even-numbered subbands and aliased to −π / 2 in the case of non-even-numbered subbands after downsampling.

  FIG. 8 shows the effect of oversampling of the complex QMF bank. For the even coefficient k band and the odd coefficient k band, respectively, the negative and positive portions of the frequency spectrum are not needed to reconstruct the (original real-valued) signal. The aforementioned portion of the frequency spectrum of the downsampled filter bank is represented as an alias band or a stop band, while the other portion is illustrated as a pass band or a non-alias band. The alias band has information that is also present in the pass band of the spectrum of the other subbands. This particular property is used to obtain an efficient coding mechanism.

  Alias and non-alias bands have redundant information, and one can be determined from the other. Furthermore, complementary interpretation of alias and non-alias bands can be used.

  Apply a specific type of additional filter bank 503 at each output of the downsampled analysis filter bank 501 and apply a specific butterfly structure 505 between the outputs of the additional filter bank 501 as shown below. Allows the energy corresponding to the alias band (or stop band) of the QMF analysis filter bank to be reduced to zero or negligible value.

  As a result, half of the information (ie, half of the filter bank output) can be discarded. The result is a critically sampled representation. This representation is very similar to the representation achieved by the MDCT transform of the original time domain samples, and thus closely resembles a subband signal generated by a normal waveform encoder such as MP3 or AAC. Thus, the waveform coding technique can be applied directly to the critical sampled signal in the waveform coding processor 507 without any requirement for time domain conversion and subsequent MDCT subband generation. . The resulting encoded data is then provided by the bitstream processor 509 in the bitstream.

  FIG. 9 shows the effect of QMF subband generation for a signal having two sine waves.

  In the complex frequency domain (eg, obtained by FFT), each sine wave appears in the spectrum as a positive frequency and as a negative frequency. Here, a complex QMF bank with 8 bands is assumed (in the example of FIG. 5, a bank with 64 bands is used). Prior to downsampling, a sine wave appears as shown in spectra AH. As shown, each sine wave is present in two subbands (eg, the low frequency spectral line is spectrum A corresponding to the first QMF subband, and spectrum B corresponding to the second QMF subband. Exists.

  The QMF bank downsampling process is shown in the lower part of FIG. Here, the spectrum I indicates a spectrum before downsampling. The downsampling process can be interpreted as follows. First, the spectrum is separated into M spectra A to H. Here, M is a downsampling coefficient (M = 8) as indicated by I and K for the first subband and the second subband, respectively. Each individual separated spectrum is once again expanded (stretched) to the full frequency range. Then, all the individual separated and extended spectra are added. Thus, a spectrum as shown in spectra J and L for the first subband and the second subband, respectively, is provided.

  In summary, each individual subband filter having a bandwidth that exceeds the frequency interval between the subbands results in signal components in two separate subbands, depending on the signal components of the time domain signal. Furthermore, one of the aforementioned signal components fits in one alias band of the subbands and one fits in a non-alias band of another subband.

  Thus, as shown in spectra J and L, in the final output spectrum of the complex QMF bank, the components are still present in the two subbands. For example, low frequency spectral lines are present in the passband of the first subband as well as the stopband of the second subband. In either case, the magnitude of the spectral line is represented by the frequency response of the (shifted) prototype filter.

  According to the embodiment of FIG. 5, a further set of complex transforms (filter bank 503) is added, where each transform is applied to the output of the subband. Using this, the frequency spectrum of the aforementioned subband is further separated into a plurality of subbands.

  Each subband in the passband of the QMF subband is then combined with the corresponding subband of the alias band in the adjacent QMF subband. In this example, a partial subband comprising a low frequency sine wave in spectrum J is combined with a low frequency sine wave in spectrum L. As a result, signal components generated from the same low frequency signal of the time domain signal are combined into a single signal component.

  In addition, to compensate for the frequency response of the QMF prototype filter, the value from each subband is weighted by the relative amplitude of the frequency response before synthesis (the amplitude response of the QMF prototype filter is constant within each subband) Is).

  Signal components in the stop band can be ignored or compensated by values from the pass band, thereby effectively reducing the energy in the alias band. Thus, the operation of transform processor 207 can be viewed as corresponding to concentrating the energy of the two signal components that occur at each frequency into a single signal component in one of the QMF subbands. Is possible. Thus, it is possible to ignore signal values in the alias band or stop band, thus achieving downsampling efficiently by half, thereby resulting in a critical sampled signal Is possible.

  As shown below, synthesis of signal components (and cancellation of signal components in alias bands) can be achieved by using a butterfly structure.

  Basically, applying another (50% overlap) complex transform to the subband signal (by filter bank 503) results in another upsampling of twice. However, the chosen transform has certain symmetric properties, which allows a 50% reduction in data. The resulting transformation can be considered equivalent to applying MDCT to real data and applying MDST to imaginary data. Both are critically sampled transformations, so no upsampling is performed.

  More specifically, the filter bank 503 may be a complex modulation filter bank having R = 2Q bands. An example of the standardized frequency response of the filter bank 503 for each subband is shown for each subband k in FIG. As can be seen, the filter banks are stacked in an odd number and do not have any subbands centered on the DC value. Rather, in this example, the center frequency of the subband is symmetric around zero and the center frequency of the first subband is about half of the subband frequency offset.

  The downsampling factor in this second bank is Q, which is the analysis filter

（r=−Q、−Q+1、…,、Q−１）によって定義される。ここで、実数値プロトタイプ・ウィンドウw(v)は、w(v)=w(−v−1−Q)であるようなものである。このウィンドウは、（３）の実数部分又は（３）の虚数部分にフィルタが等しいフィルタ・バンク内の解析から完全な再構成を達成することが可能であるように企図することが可能である。前述の場合、Ｒ＝２Ｑ個のサブバンドのＱのみでよい（正の周波数又は負の周波数）。顕著な例には、修正離散コサイン変換ＭＤＣＴがある。

(R = −Q, −Q + 1,..., Q−1). Here, the real value prototype window w (v) is such that w (v) = w (−v−1−Q). This window can be designed such that a complete reconstruction can be achieved from analysis in the filter bank where the filter is equal to the real part of (3) or the imaginary part of (3). In the case described above, only Q of R = 2Q subbands is required (positive frequency or negative frequency). A prominent example is the modified discrete cosine transform MDCT.

  However, in the embodiment of FIG. 5, the complex value signal z (n) is instead analyzed by the filter 503 and the resulting signal is downsampled by a factor of Q and the real part is taken. Corresponding synthesis operation is Q-times upsampling, complex modulation filter

によって合成フィルタリングする工程と、R=２Q個のサブバンドにわたって結果を合計する工程であって、r=−Q、−Q+1,…,Q−１である工程と、最後に、結果を２で除算する工程とを有している。

Combining and filtering the results over R = 2Q subbands, where r = −Q, −Q + 1,..., Q−1, and finally the result 2 And dividing by.

  If the prototype window w (y) is intended to provide a complete reconstruction in the real bank, the complex signal z (n) is completely reconstructed by a combination of analysis and synthesis in the complex case. Composed. To see this, C represents an analysis bank with an analysis filter equal to the real part of (3), and S represents an analysis bank with an analysis filter equal to-(imaginary part of (3)) And In that case, the complex analysis bank (3) can be described as E = C−iS. By describing the complex signal as z = ζ + iη,

が得られる。

Is obtained.

  Here, (5) is obtained for positive frequencies r = 0,..., Q−1 and negative frequencies r = −Q,. Replacing r with −1−r in (3) leads to the complex conjugate of the analysis filter. Therefore, according to the analysis (5), Cζ + Sη and Cζ−Sη in the case of positive frequencies r = 0,. Access to is provided. In the case of synthesis, this information can be easily re-synthesized into Cζ and Sη. From there, a complete reconstruction of ζ and η is possible with the corresponding real value synthesis bank. The simple details proving the claim that this reconstruction is equivalent to the operations of complex analysis, real part, complex synthesis, and division by two are omitted.

  This filter bank structure is “Modified DFT Filter Banks with Perfect Reconstruction, IEEE Transactions on Circuits and Systems-II: Analog and Digital Signal Processing, Vol. 46, No. 11, November 1999” by Karp T., Fliege NJ. Are not identical but related. The main difference is that the filter banks of the present application are stacked in odd numbers. This is effective in the hybrid structure proposed below.

For k = 0, 1,..., M−1 and r = −Q, −Q + 1,..., Q−1, v _{k, r} (n) is converted to a complex QMF analysis signal y _k ( v) is analyzed, down-sampled to 1 / Q, and a partial subband signal achieved by taking the real part. This results in a total of 2QM real valued signals at the sampling rate 1 / (QM) of the original sampling rate. Therefore, a representation oversampled twice is obtained. Referring to FIG. 8 and FIG.

によって定義することが好都合である。同様に、前述したストップ・バンド信号又は「エイリアス・バンド」信号は、

It is convenient to define by Similarly, the stop band signal or “alias band” signal described above is

によって定義される。

Defined by

  Both of the above signals are critically sampled.

  The next step is when the time signal is a pure sine wave at the frequency π / (2M) ≦ Ω ≦ π−π / (2M), and θ = 0 in (1),

であることを利用するものである。ここで、Cは複素定数である。その結果、隣接QMFバンドはよって、同じ周波数及び位相を有しているが、異なる振幅を有している（変調線形位相QMFプロトタイプ・フィルタの応答による）複素正弦波を有する。よって、前述の通り、２つの信号成分（１つのQMFサブバンドのパス・バンド内の１つ、及び隣接サブバンドのエイリアス・バンド内の１つ）が生じる。

It is something that uses that. Here, C is a complex constant. As a result, adjacent QMF bands thus have complex sinusoids (due to the response of the modulated linear phase QMF prototype filter) that have the same frequency and phase but different amplitudes. Thus, as described above, two signal components are generated (one in the pass band of one QMF subband and one in the alias band of the adjacent subband).

  Converting the corresponding pair of subband samples into weighted sums and differences thus leads to very slight differences. Before summarizing the details of this transformation, it should be pointed out that if the assumption that θ = 0 is not satisfied, the QMF sample is preferably

によって調整前プロセッサ５１１内で予め乗算すること（調節前処理）によって位相補償すべきであることである。

Therefore, phase compensation should be performed by pre-multiplication (pre-adjustment processing) in the pre-adjustment processor 511.

  Alternatively, further phase jumps of kπ in the pre-adjustment processor can be handled by sign inversion with a butterfly structure.

  For k = 0, ..., M-2, the sum and difference signals are

によって定義される。

Defined by

  For the first QMF band and the last QMF band, the definition is

によって置き換えられる。

Replaced by

  FIG. 11 shows the corresponding conversion butterfly structure. The butterfly structure described above is the same as that used for MPEG-1 Layer III (MP3). However, an important difference is to use the so-called anti-aliased butterfly of mp3 to reduce aliasing in the pass band of the real value filter bank. In a real modulation filter bank, it is not possible to distinguish between positive and negative (complex) frequencies in a subband. In the synthesis process, one sine wave in the subband thus generally leads to two sine waves in the output. One of these (ie the aliased sine wave) is far away from the correct frequency. Real bank anti-aliased butterfly aims to suppress aliased sine waves by inducing a second hybrid bank synthesis into two adjacent real QMF bands. The present technique is fundamentally different from the above case in that the complex QMF subband is supplied with a complex sine wave from the second hybrid bank. This results in only one precisely located sine wave in the final output and does not cause any MP3 aliasing problems. The butterfly structure 505 is simply intended to correct the combined analytic operation and the amplitude response of the combined operation when the difference signal d is omitted.

First, when the transform coefficients are set to β _{k, γ} = 1 and α _{k, γ} = 0, the signal pair (s, d) is simply a duplicate of the pair (b, a). This can be done in a selective way. This is because the structures of (10) and (11) are such that in-place calculation can be performed. This is important when the hybrid filter bank structure is invoked only for a subset of QMF bands. All sum and difference operations

である限り反転可能であり、

Can be reversed as long as

の場合、変換は直交である。

In the case of, the transformation is orthogonal.

The corresponding synthesis steps are very similar to (10) and (11) and will be apparent to those skilled in the art. This also applies to the inversion of pre-adjustment processing by the pre-adjustment processor 511. The method of this application is that β _{k, Q−1−r} = β _{k, r} and the signal d _{k, r} (n) is very high in the case of α _{k, Q−1−r} = α _{k, r.} Less and

であり、Kが正規化定数であることを教示している。

And teaches that K is a normalization constant.

  Assuming that an additional filter bank per subband k is critically sampled and fully reconstructed, the approximation of the alias band partial subband domain signal effectively replaces the oversampled representation with the original time. Change to a critically sampled representation that closely resembles the MDCT of the region sample. This allows for efficient encoding of complex subband domain signals in a manner similar to known perceptual waveform encoders. The reconstruction error of discarding the transform coefficients corresponding to the stop band or alias band is about 34 dB for the normal transform length Q = 16.

  Alternatively, the coefficient corresponding to the stop band or alias band can be further encoded into the coefficient corresponding to the pass band to obtain a more suitable reconstruction. This may be advantageous when Q is very small (eg, Q <8) or when the performance of the QMF bank is poor.

  In the example of FIG. 5, the signal pair (s, d) is obtained by applying the sum / difference butterfly 505 of (10) and (11). Of these, in this case, only the dominant component is maintained. In the next step, for example, a normal waveform encoding technique using scale coefficient encoding and quantization is applied to the resulting signal. The coding coefficients are embedded in the bit stream.

  The decoder follows the reverse process. First, the coefficients are demultiplexed from the bit stream and decoded. The encoder then performs an inverse butterfly operation followed by synthesis filtering and post-adjustment processing to obtain a complex subband domain signal. The aforementioned signal can finally be converted to the time domain by a QMF synthesis bank.

  The above description for clarity has described embodiments of the invention with reference to various functional devices and processors. However, it will be apparent that any suitable distribution of functionality between separate functional devices or processors can be used without detracting from the invention. For example, functions shown as being performed by separate processors or controllers can be performed by the same processor or controller. Thus, a reference to a particular functional device is not to indicate a strict logical or physical structure or organization, but is merely to be regarded as a reference to a suitable means for providing the aforementioned functions.

  The present invention can be implemented in any suitable form including hardware, software, firmware, or any combination thereof. Optionally, the present invention may be implemented at least in part as computer software running on one or more data processors and / or digital signal processors. The components and components of the embodiments of the invention may be physically, functionally and logically implemented in any suitable way. Indeed, the functions can be implemented in a single device, in multiple devices, or as part of other functional devices. As such, the present invention can be implemented in a single device or can be physically and functionally distributed across separate devices and processors.

  Although the invention has been described with reference to specific embodiments, it is not intended to be limited to the specific form set forth in the specification and claims. Rather, the scope of the present invention is limited only by the claims. Further, although it may appear that the features are described with respect to particular embodiments, those skilled in the art will recognize that the various features of the foregoing embodiments can be combined according to the present invention. In the claims, the word comprising does not exclude the presence of other elements or steps.

  Furthermore, although individually listed, a plurality of means, components or method steps may be implemented by, for example, a single apparatus or processor. Further, although individual features may be provided in separate claims, in some cases they may be combined effectively, so that separate claims provide that a combination of features is not feasible and / or It does not suggest that it is not effective. Furthermore, having a feature in one claim category does not suggest limiting to this category, but rather indicates that the feature is applicable as appropriate to other claim categories. Further, the order of composition in the claims does not imply any particular order in which the composition must be performed, and in particular, the order of the individual steps in a method claim must be performed in this order. It does not suggest that it should not be. Rather, the steps can be performed in any suitable order. Further, the singular forms do not exclude the plural. Thus, references to “a”, “an”, “first”, “second”, etc. do not exclude the plural. Reference signs in the claims provided merely as a clarifying example shall not be construed as limiting the claims in any way.

1 shows a transmission system 100 for communication of audio signals according to a specific embodiment of the invention. FIG. 3 shows an encoder according to a particular embodiment of the invention. FIG. 3 shows an example of a particular element of an encoder according to a particular embodiment of the invention. FIG. 3 shows a decoder according to a particular embodiment of the invention. FIG. 3 shows an encoder according to a particular embodiment of the invention. It is a figure which shows the example of the filter bank of an analysis and a synthesis | combination. It is a figure which shows the example of the spectrum of a QMF filter bank. FIG. 6 is a diagram illustrating an example of a downsampled QMF subband filter spectrum. It is a figure which shows the example of the spectrum of a QMF subband. It is a figure which shows the example of the spectrum of a subband filter bank. It is a figure which shows the example of a butterfly transformation structure.

Claims (28)

A decoder for generating a time domain audio signal by waveform decoding,
Means for receiving an encoded data stream;
Means for generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is a complex sub-sampled critically sampled of the time domain audio signal. Means corresponding to the band domain signal representation;
Transform means for generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a non-critical sampled complex subband of the time domain audio signal Conversion means corresponding to the region representation;
A decoder comprising a synthesis filter bank for generating the time domain audio signal from the second subband signal.   The decoder according to claim 1, wherein each subband of the first subband signal includes a plurality of partial subbands, and the converting means converts the subband of the second subband signal to the subband. A decoder comprising a second synthesis filter bank generated from partial subbands of the first subband signal.   3. The decoder according to claim 2, wherein each subband of the second subband signal includes an alias band and a non-alias band, and the converting means includes the first subband signal. Separating a partial subband into an aliased partial subband of a first subband band of the second subband signal and a non-aliased subband of a second subband of the second subband signal; The alias subband and the non-alias subband have a corresponding frequency interval in a time domain signal.   4. A decoder according to claim 3, wherein the separating means has a butterfly structure. An encoder for encoding a time domain audio signal,
Means for receiving the time domain audio signal;
A first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal corresponds to a complex subband domain representation obtained by non-critically sampling the time domain signal A first filter bank to
Transform means for generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a complex subband region obtained by critical sampling the time domain audio signal. Conversion means corresponding to the expression;
Means for generating a waveform encoded data stream by encoding data values of the second subband signal.   6. The encoder of claim 5, further comprising means for parametrically encoding the time domain audio signal using the first subband signal.   6. The encoder according to claim 5, wherein the converting means includes a second filter bank that generates a plurality of partial subbands for each subband of the first subband signal.   8. The encoder of claim 7, wherein the second filter bank is stacked with an odd number.   8. The encoder of claim 7, wherein each subband includes a specific alias subband corresponding to an alias band of the subband and a specific nonaliased portion corresponding to a non-alias band of the subband. And the converting means comprises combining means for combining the aliased subband of the first subband band with the non-aliased partial subband of the second subband, and the alias part. The subband and the non-aliased partial subband are encoders having corresponding frequency intervals in the time domain signal.   The encoder of claim 9, wherein the combining means is configured to reduce energy in the alias band.   10. The encoder of claim 9, wherein the combining means includes non-aliasing of a first alias partial subband in the first subband and a first non-alias partial subband in the second subband. An encoder comprising means for generating an aliased sum signal.   12. The encoder according to claim 11, wherein the synthesizing means includes a butterfly structure for generating the non-aliased sum signal.   The encoder according to claim 12, wherein at least one coefficient of the butterfly structure depends on a frequency response of a filter of the first filter bank.   10. An encoder according to claim 9, wherein the transforming means is configured not to comprise the alias band data values in the encoded data stream.   6. The encoder of claim 5, further comprising means for performing non-aliased signal processing on the first subband signal prior to conversion to the second signal.   6. The encoder of claim 5 further comprising means for phase compensating the first subband signal prior to conversion to the second signal.   6. The encoder of claim 5, wherein the first filter bank is a QMF filter bank. A method for generating a time domain audio signal by waveform decoding, comprising:
Receiving an encoded data stream; and
Generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is a complex sub-sampled critically sampled of the time domain audio signal; A process corresponding to the band domain signal representation;
Generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a non-critical sample of the time domain audio signal; A process corresponding to the expression;
Generating a time domain audio signal from the second subband signal. A method of encoding a time domain audio signal, comprising:
Receiving the time domain audio signal;
A first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is a non-critically sampled time domain signal; A process corresponding to
Generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a critical subsample of the time domain audio signal; A process corresponding to
Means for generating a waveform encoded data stream by encoding data values of the second subband signal. A receiver for receiving an audio signal,
Means for receiving an encoded data stream;
Means for generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is a critical subsample of a time domain audio signal; Means corresponding to the region signal representation;
Transform means for generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a non-critical sampled complex subband of the time domain audio signal Conversion means corresponding to the region representation;
And a synthesis filter bank for generating a time-domain audio signal from the second subband signal. A transmitter for transmitting an encoded audio signal, the transmitter comprising:
Means for receiving a time domain audio signal;
A first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal corresponds to a complex subband domain representation obtained by non-critically sampling the time domain signal A first filter bank to
Transform means for generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a complex subband region obtained by critical sampling the time domain audio signal. Conversion means corresponding to the expression;
A transmitter comprising means for generating a waveform encoded data stream by encoding data values of the second subband signal, and means for transmitting the waveform encoded data stream. A transmission system for transmitting time domain audio signals,
A transmitter,
Means for receiving the time domain audio signal;
A first filter bank for generating a first subband signal from the time domain audio signal, wherein the first subband signal corresponds to a complex subband domain representation obtained by non-critically sampling the time domain signal A first filter bank to
Transform means for generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a complex subband region obtained by critical sampling the time domain audio signal. Conversion means corresponding to the expression;
Means for generating a waveform encoded data stream by encoding data values of the second subband signal;
Means for transmitting said waveform encoded data stream; and
A receiver,
Means for receiving the waveform encoded data stream;
Means for generating a third subband signal by decoding data values of the encoded data stream, wherein the third subband signal is a complex sub-sample that is critically sampled from the time domain audio signal; Means corresponding to the band-domain signal;
Transform means for generating a fourth subband signal from the third subband signal by subband processing, wherein the fourth subband signal is a complex subband obtained by non-critically sampling the time domain audio signal. Conversion means corresponding to the region representation;
And a receiver comprising a synthesis filter bank for generating a time-domain audio signal from the fourth subband signal. A method for receiving an audio signal, comprising:
Receiving an encoded data stream; and
Generating a first subband signal by decoding data values of the encoded data stream, wherein the first subband signal is a critical subsample of a time domain audio signal; A process corresponding to the region signal representation;
Generating a second sub-band signal from the first sub-band signal by a sub-band signal, wherein the second sub-band signal is a non-critical sampling of the time-domain audio signal; A process corresponding to the expression;
Generating a time domain audio signal from the second subband signal. A method for transmitting an encoded audio signal, comprising:
Receiving a time domain audio signal;
A first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is a non-critically sampled complex subband of the time domain signal; A process corresponding to the region representation;
Generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a critical subsample of the time domain audio signal; A process corresponding to
A method comprising: generating a waveform encoded data stream by encoding data values of the second subband signal; and transmitting the waveform encoded data stream. A method for transmitting and receiving time domain audio signals, comprising:
The transmitter is
Receiving the time domain audio signal;
A first filter bank generating a first subband signal from the time domain audio signal, wherein the first subband signal is a non-critically sampled time domain signal; A process corresponding to
Generating a second subband signal from the first subband signal by subband processing, wherein the second subband signal is a critical subsample of the time domain audio signal; A process corresponding to
Generating a waveform encoded data stream by encoding data values of the second subband signal;
Transmitting the waveform encoded data stream;
The receiver
Receiving the waveform encoded data stream;
Generating a third subband signal by decoding data values of the encoded data stream, wherein the third subband signal is a complex sub-sample obtained by critically sampling the time domain audio signal; A process corresponding to the band domain signal representation;
Generating a fourth subband signal from the third subband signal by subband processing, wherein the fourth subband signal is a non-critically sampled time domain audio signal; A process corresponding to the expression;
Generating a time domain audio signal from the fourth subband signal.   A computer program for executing the method according to any of claims 18, 19, 23, 24 or 25.   An audio reproducing apparatus comprising the decoder according to claim 1.   6. An audio recording device comprising the encoder according to claim 5.

Images